int getla() { processor_set_t default_set; kern_return_t error; unsigned int info_count; struct processor_set_basic_info info; host_t host; error = processor_set_default(host_self(), &default_set); if (error != KERN_SUCCESS) return -1; info_count = PROCESSOR_SET_BASIC_INFO_COUNT; if (processor_set_info(default_set, PROCESSOR_SET_BASIC_INFO, &host, (processor_set_info_t) & info, &info_count) != KERN_SUCCESS) return -1; return (int) (info.load_average + (LOAD_SCALE / 2)) / LOAD_SCALE; }
int mach_load_avg(void) { kern_return_t status; host_t host; unsigned int info_count; struct processor_set_basic_info info; processor_set_t default_set; status=processor_set_default(host_self(), &default_set); if (status!=KERN_SUCCESS) { mach_error("Error calling processor_set_default", status); exit(1); } info_count=PROCESSOR_SET_BASIC_INFO_COUNT; status=processor_set_info(default_set, PROCESSOR_SET_BASIC_INFO, &host, (processor_set_info_t)&info, &info_count); #ifdef DEBUG if (status != KERN_SUCCESS) mach_error("Error calling processor_set_info", status); #endif return info.load_average; }
int getloadavg (double loadavg[], int nelem) { int elem = 0; /* Return value. */ # ifdef NO_GET_LOAD_AVG # define LDAV_DONE /* Set errno to zero to indicate that there was no particular error; this function just can't work at all on this system. */ errno = 0; elem = -1; # endif # if !defined (LDAV_DONE) && defined (HAVE_LIBKSTAT) /* Use libkstat because we don't have to be root. */ # define LDAV_DONE kstat_ctl_t *kc; kstat_t *ksp; kstat_named_t *kn; kc = kstat_open (); if (kc == 0) return -1; ksp = kstat_lookup (kc, "unix", 0, "system_misc"); if (ksp == 0) return -1; if (kstat_read (kc, ksp, 0) == -1) return -1; kn = kstat_data_lookup (ksp, "avenrun_1min"); if (kn == 0) { /* Return -1 if no load average information is available. */ nelem = 0; elem = -1; } if (nelem >= 1) loadavg[elem++] = (double) kn->value.ul / FSCALE; if (nelem >= 2) { kn = kstat_data_lookup (ksp, "avenrun_5min"); if (kn != 0) { loadavg[elem++] = (double) kn->value.ul / FSCALE; if (nelem >= 3) { kn = kstat_data_lookup (ksp, "avenrun_15min"); if (kn != 0) loadavg[elem++] = (double) kn->value.ul / FSCALE; } } } kstat_close (kc); # endif /* HAVE_LIBKSTAT */ # if !defined (LDAV_DONE) && defined (hpux) && defined (HAVE_PSTAT_GETDYNAMIC) /* Use pstat_getdynamic() because we don't have to be root. */ # define LDAV_DONE # undef LOAD_AVE_TYPE struct pst_dynamic dyn_info; if (pstat_getdynamic (&dyn_info, sizeof (dyn_info), 0, 0) < 0) return -1; if (nelem > 0) loadavg[elem++] = dyn_info.psd_avg_1_min; if (nelem > 1) loadavg[elem++] = dyn_info.psd_avg_5_min; if (nelem > 2) loadavg[elem++] = dyn_info.psd_avg_15_min; # endif /* hpux && HAVE_PSTAT_GETDYNAMIC */ # if ! defined LDAV_DONE && defined HAVE_LIBPERFSTAT # define LDAV_DONE # undef LOAD_AVE_TYPE /* Use perfstat_cpu_total because we don't have to be root. */ { perfstat_cpu_total_t cpu_stats; int result = perfstat_cpu_total (NULL, &cpu_stats, sizeof cpu_stats, 1); if (result == -1) return result; loadavg[0] = cpu_stats.loadavg[0] / (double)(1 << SBITS); loadavg[1] = cpu_stats.loadavg[1] / (double)(1 << SBITS); loadavg[2] = cpu_stats.loadavg[2] / (double)(1 << SBITS); elem = 3; } # endif # if !defined (LDAV_DONE) && (defined (__linux__) || defined (__CYGWIN__)) # define LDAV_DONE # undef LOAD_AVE_TYPE # ifndef LINUX_LDAV_FILE # define LINUX_LDAV_FILE "/proc/loadavg" # endif char ldavgbuf[3 * (INT_STRLEN_BOUND (int) + sizeof ".00 ")]; char const *ptr = ldavgbuf; int fd, count; fd = open (LINUX_LDAV_FILE, O_RDONLY); if (fd == -1) return -1; count = read (fd, ldavgbuf, sizeof ldavgbuf - 1); (void) close (fd); if (count <= 0) return -1; ldavgbuf[count] = '\0'; for (elem = 0; elem < nelem; elem++) { char *endptr; double d; errno = 0; d = c_strtod (ptr, &endptr); if (ptr == endptr || (d == 0 && errno != 0)) { if (elem == 0) return -1; break; } loadavg[elem] = d; ptr = endptr; } return elem; # endif /* __linux__ || __CYGWIN__ */ # if !defined (LDAV_DONE) && defined (__NetBSD__) # define LDAV_DONE # undef LOAD_AVE_TYPE # ifndef NETBSD_LDAV_FILE # define NETBSD_LDAV_FILE "/kern/loadavg" # endif unsigned long int load_ave[3], scale; int count; FILE *fp; fp = fopen (NETBSD_LDAV_FILE, "r"); if (fp == NULL) return -1; count = fscanf (fp, "%lu %lu %lu %lu\n", &load_ave[0], &load_ave[1], &load_ave[2], &scale); (void) fclose (fp); if (count != 4) return -1; for (elem = 0; elem < nelem; elem++) loadavg[elem] = (double) load_ave[elem] / (double) scale; return elem; # endif /* __NetBSD__ */ # if !defined (LDAV_DONE) && defined (NeXT) # define LDAV_DONE /* The NeXT code was adapted from iscreen 3.2. */ host_t host; struct processor_set_basic_info info; unsigned int info_count; /* We only know how to get the 1-minute average for this system, so even if the caller asks for more than 1, we only return 1. */ if (!getloadavg_initialized) { if (processor_set_default (host_self (), &default_set) == KERN_SUCCESS) getloadavg_initialized = true; } if (getloadavg_initialized) { info_count = PROCESSOR_SET_BASIC_INFO_COUNT; if (processor_set_info (default_set, PROCESSOR_SET_BASIC_INFO, &host, (processor_set_info_t) &info, &info_count) != KERN_SUCCESS) getloadavg_initialized = false; else { if (nelem > 0) loadavg[elem++] = (double) info.load_average / LOAD_SCALE; } } if (!getloadavg_initialized) return -1; # endif /* NeXT */ # if !defined (LDAV_DONE) && defined (UMAX) # define LDAV_DONE /* UMAX 4.2, which runs on the Encore Multimax multiprocessor, does not have a /dev/kmem. Information about the workings of the running kernel can be gathered with inq_stats system calls. We only know how to get the 1-minute average for this system. */ struct proc_summary proc_sum_data; struct stat_descr proc_info; double load; register unsigned int i, j; if (cpus == 0) { register unsigned int c, i; struct cpu_config conf; struct stat_descr desc; desc.sd_next = 0; desc.sd_subsys = SUBSYS_CPU; desc.sd_type = CPUTYPE_CONFIG; desc.sd_addr = (char *) &conf; desc.sd_size = sizeof conf; if (inq_stats (1, &desc)) return -1; c = 0; for (i = 0; i < conf.config_maxclass; ++i) { struct class_stats stats; bzero ((char *) &stats, sizeof stats); desc.sd_type = CPUTYPE_CLASS; desc.sd_objid = i; desc.sd_addr = (char *) &stats; desc.sd_size = sizeof stats; if (inq_stats (1, &desc)) return -1; c += stats.class_numcpus; } cpus = c; samples = cpus < 2 ? 3 : (2 * cpus / 3); } proc_info.sd_next = 0; proc_info.sd_subsys = SUBSYS_PROC; proc_info.sd_type = PROCTYPE_SUMMARY; proc_info.sd_addr = (char *) &proc_sum_data; proc_info.sd_size = sizeof (struct proc_summary); proc_info.sd_sizeused = 0; if (inq_stats (1, &proc_info) != 0) return -1; load = proc_sum_data.ps_nrunnable; j = 0; for (i = samples - 1; i > 0; --i) { load += proc_sum_data.ps_nrun[j]; if (j++ == PS_NRUNSIZE) j = 0; } if (nelem > 0) loadavg[elem++] = load / samples / cpus; # endif /* UMAX */ # if !defined (LDAV_DONE) && defined (DGUX) # define LDAV_DONE /* This call can return -1 for an error, but with good args it's not supposed to fail. The first argument is for no apparent reason of type `long int *'. */ dg_sys_info ((long int *) &load_info, DG_SYS_INFO_LOAD_INFO_TYPE, DG_SYS_INFO_LOAD_VERSION_0); if (nelem > 0) loadavg[elem++] = load_info.one_minute; if (nelem > 1) loadavg[elem++] = load_info.five_minute; if (nelem > 2) loadavg[elem++] = load_info.fifteen_minute; # endif /* DGUX */ # if !defined (LDAV_DONE) && defined (apollo) # define LDAV_DONE /* Apollo code from [email protected] (Ray Lischner). This system call is not documented. The load average is obtained as three long integers, for the load average over the past minute, five minutes, and fifteen minutes. Each value is a scaled integer, with 16 bits of integer part and 16 bits of fraction part. I'm not sure which operating system first supported this system call, but I know that SR10.2 supports it. */ extern void proc1_$get_loadav (); unsigned long load_ave[3]; proc1_$get_loadav (load_ave); if (nelem > 0) loadavg[elem++] = load_ave[0] / 65536.0; if (nelem > 1) loadavg[elem++] = load_ave[1] / 65536.0; if (nelem > 2) loadavg[elem++] = load_ave[2] / 65536.0; # endif /* apollo */ # if !defined (LDAV_DONE) && defined (OSF_MIPS) # define LDAV_DONE struct tbl_loadavg load_ave; table (TBL_LOADAVG, 0, &load_ave, 1, sizeof (load_ave)); loadavg[elem++] = (load_ave.tl_lscale == 0 ? load_ave.tl_avenrun.d[0] : (load_ave.tl_avenrun.l[0] / (double) load_ave.tl_lscale)); # endif /* OSF_MIPS */ # if !defined (LDAV_DONE) && (defined (__MSDOS__) || defined (WINDOWS32)) # define LDAV_DONE /* A faithful emulation is going to have to be saved for a rainy day. */ for ( ; elem < nelem; elem++) { loadavg[elem] = 0.0; } # endif /* __MSDOS__ || WINDOWS32 */ # if !defined (LDAV_DONE) && defined (OSF_ALPHA) # define LDAV_DONE struct tbl_loadavg load_ave; table (TBL_LOADAVG, 0, &load_ave, 1, sizeof (load_ave)); for (elem = 0; elem < nelem; elem++) loadavg[elem] = (load_ave.tl_lscale == 0 ? load_ave.tl_avenrun.d[elem] : (load_ave.tl_avenrun.l[elem] / (double) load_ave.tl_lscale)); # endif /* OSF_ALPHA */ # if ! defined LDAV_DONE && defined __VMS /* VMS specific code -- read from the Load Ave driver. */ LOAD_AVE_TYPE load_ave[3]; static bool getloadavg_initialized; # ifdef eunice struct { int dsc$w_length; char *dsc$a_pointer; } descriptor; # endif /* Ensure that there is a channel open to the load ave device. */ if (!getloadavg_initialized) { /* Attempt to open the channel. */ # ifdef eunice descriptor.dsc$w_length = 18; descriptor.dsc$a_pointer = "$$VMS_LOAD_AVERAGE"; # else $DESCRIPTOR (descriptor, "LAV0:"); # endif if (sys$assign (&descriptor, &channel, 0, 0) & 1) getloadavg_initialized = true; } /* Read the load average vector. */ if (getloadavg_initialized && !(sys$qiow (0, channel, IO$_READVBLK, 0, 0, 0, load_ave, 12, 0, 0, 0, 0) & 1)) { sys$dassgn (channel); getloadavg_initialized = false; } if (!getloadavg_initialized) return -1; # endif /* ! defined LDAV_DONE && defined __VMS */ # if ! defined LDAV_DONE && defined LOAD_AVE_TYPE && ! defined __VMS /* UNIX-specific code -- read the average from /dev/kmem. */ # define LDAV_PRIVILEGED /* This code requires special installation. */ LOAD_AVE_TYPE load_ave[3]; /* Get the address of LDAV_SYMBOL. */ if (offset == 0) { # ifndef sgi # if ! defined NLIST_STRUCT || ! defined N_NAME_POINTER strcpy (nl[0].n_name, LDAV_SYMBOL); strcpy (nl[1].n_name, ""); # else /* NLIST_STRUCT */ # ifdef HAVE_STRUCT_NLIST_N_UN_N_NAME nl[0].n_un.n_name = LDAV_SYMBOL; nl[1].n_un.n_name = 0; # else /* not HAVE_STRUCT_NLIST_N_UN_N_NAME */ nl[0].n_name = LDAV_SYMBOL; nl[1].n_name = 0; # endif /* not HAVE_STRUCT_NLIST_N_UN_N_NAME */ # endif /* NLIST_STRUCT */ # ifndef SUNOS_5 if ( # if !(defined (_AIX) && !defined (ps2)) nlist (KERNEL_FILE, nl) # else /* _AIX */ knlist (nl, 1, sizeof (nl[0])) # endif >= 0) /* Omit "&& nl[0].n_type != 0 " -- it breaks on Sun386i. */ { # ifdef FIXUP_KERNEL_SYMBOL_ADDR FIXUP_KERNEL_SYMBOL_ADDR (nl); # endif offset = nl[0].n_value; } # endif /* !SUNOS_5 */ # else /* sgi */ int ldav_off; ldav_off = sysmp (MP_KERNADDR, MPKA_AVENRUN); if (ldav_off != -1) offset = (long int) ldav_off & 0x7fffffff; # endif /* sgi */ } /* Make sure we have /dev/kmem open. */ if (!getloadavg_initialized) { # ifndef SUNOS_5 channel = open ("/dev/kmem", O_RDONLY); if (channel >= 0) { /* Set the channel to close on exec, so it does not litter any child's descriptor table. */ set_cloexec_flag (channel, true); getloadavg_initialized = true; } # else /* SUNOS_5 */ /* We pass 0 for the kernel, corefile, and swapfile names to use the currently running kernel. */ kd = kvm_open (0, 0, 0, O_RDONLY, 0); if (kd != 0) { /* nlist the currently running kernel. */ kvm_nlist (kd, nl); offset = nl[0].n_value; getloadavg_initialized = true; } # endif /* SUNOS_5 */ } /* If we can, get the load average values. */ if (offset && getloadavg_initialized) { /* Try to read the load. */ # ifndef SUNOS_5 if (lseek (channel, offset, 0) == -1L || read (channel, (char *) load_ave, sizeof (load_ave)) != sizeof (load_ave)) { close (channel); getloadavg_initialized = false; } # else /* SUNOS_5 */ if (kvm_read (kd, offset, (char *) load_ave, sizeof (load_ave)) != sizeof (load_ave)) { kvm_close (kd); getloadavg_initialized = false; } # endif /* SUNOS_5 */ } if (offset == 0 || !getloadavg_initialized) return -1; # endif /* ! defined LDAV_DONE && defined LOAD_AVE_TYPE && ! defined __VMS */ # if !defined (LDAV_DONE) && defined (LOAD_AVE_TYPE) /* Including VMS. */ if (nelem > 0) loadavg[elem++] = LDAV_CVT (load_ave[0]); if (nelem > 1) loadavg[elem++] = LDAV_CVT (load_ave[1]); if (nelem > 2) loadavg[elem++] = LDAV_CVT (load_ave[2]); # define LDAV_DONE # endif /* !LDAV_DONE && LOAD_AVE_TYPE */ # if !defined LDAV_DONE /* Set errno to zero to indicate that there was no particular error; this function just can't work at all on this system. */ errno = 0; elem = -1; # endif return elem; }
int getloadavg (double loadavg[], int nelem) { int elem = 0; /* Return value. */ #ifdef NO_GET_LOAD_AVG #define LDAV_DONE /* Set errno to zero to indicate that there was no particular error; this function just can't work at all on this system. */ errno = 0; elem = -2; #endif /* NO_GET_LOAD_AVG */ #if ! defined (LDAV_DONE) && defined (HAVE_KSTAT_H) && defined (HAVE_LIBKSTAT) #define LDAV_DONE /* getloadavg is best implemented using kstat (kernel stats), on systems (like SunOS5) that support it, since you don't need special privileges to use it. Initial implementation courtesy Zlatko Calusic <*****@*****.**>. Integrated to XEmacs by Hrvoje Niksic <*****@*****.**>. Additional cleanup by Hrvoje Niksic, based on code published by Casper Dik <*****@*****.**>. */ kstat_ctl_t *kc; kstat_t *ksp; static char *avestrings[] = { "avenrun_1min", "avenrun_5min", "avenrun_15min" }; if (nelem > countof (avestrings)) nelem = countof (avestrings); kc = kstat_open (); if (!kc) return -1; ksp = kstat_lookup (kc, "unix", 0, "system_misc"); if (!ksp) { kstat_close (kc); return -1; } if (kstat_read (kc, ksp, 0) < 0) { kstat_close (kc); return -1; } for (elem = 0; elem < nelem; elem++) { kstat_named_t *kn = (kstat_named_t *) kstat_data_lookup (ksp, avestrings[elem]); if (!kn) { kstat_close (kc); return -1; } loadavg[elem] = (double)kn->value.ul / FSCALE; } kstat_close (kc); #endif /* HAVE_KSTAT_H && HAVE_LIBKSTAT */ #if !defined (LDAV_DONE) && defined (HAVE_SYS_PSTAT_H) #define LDAV_DONE /* This is totally undocumented, and is not guaranteed to work, but mayhap it might .... If it does work, it will work only on HP-UX 8.0 or later. -- Darryl Okahata <*****@*****.**> */ #undef LOAD_AVE_TYPE /* Make sure these don't exist. */ #undef LOAD_AVE_CVT #undef LDAV_SYMBOL struct pst_dynamic procinfo; union pstun statbuf; statbuf.pst_dynamic = &procinfo; if (pstat (PSTAT_DYNAMIC, statbuf, sizeof (struct pst_dynamic), 0, 0) == -1) return (-1); loadavg[elem++] = procinfo.psd_avg_1_min; loadavg[elem++] = procinfo.psd_avg_5_min; loadavg[elem++] = procinfo.psd_avg_15_min; #endif /* HPUX */ #if !defined (LDAV_DONE) && defined (__linux__) #define LDAV_DONE #undef LOAD_AVE_TYPE #ifndef LINUX_LDAV_FILE #define LINUX_LDAV_FILE "/proc/loadavg" #endif char ldavgbuf[40]; double load_ave[3]; int fd, count; fd = open (LINUX_LDAV_FILE, O_RDONLY); if (fd == -1) return -1; count = read (fd, ldavgbuf, 40); (void) close (fd); if (count <= 0) return -1; count = sscanf (ldavgbuf, "%lf %lf %lf", &load_ave[0], &load_ave[1], &load_ave[2]); if (count < 1) return -1; for (elem = 0; elem < nelem && elem < count; elem++) loadavg[elem] = load_ave[elem]; #endif /* __linux__ */ #if !defined (LDAV_DONE) && defined (__NetBSD__) || defined (__OpenBSD__) #define LDAV_DONE #undef LOAD_AVE_TYPE #ifndef NETBSD_LDAV_FILE #define NETBSD_LDAV_FILE "/kern/loadavg" #endif unsigned long int load_ave[3], scale; int count; FILE *fp; fp = fopen (NETBSD_LDAV_FILE, "r"); if (fp == NULL) return -1; count = fscanf (fp, "%lu %lu %lu %lu\n", &load_ave[0], &load_ave[1], &load_ave[2], &scale); (void) fclose (fp); if (count != 4) return -1; for (elem = 0; elem < nelem; elem++) loadavg[elem] = (double) load_ave[elem] / (double) scale; #endif /* __NetBSD__ or __OpenBSD__ */ #if !defined (LDAV_DONE) && defined (NeXT) #define LDAV_DONE /* The NeXT code was adapted from iscreen 3.2. */ host_t host; struct processor_set_basic_info info; unsigned info_count; /* We only know how to get the 1-minute average for this system, so even if the caller asks for more than 1, we only return 1. */ if (!getloadavg_initialized) { if (processor_set_default (host_self (), &default_set) == KERN_SUCCESS) getloadavg_initialized = 1; } if (getloadavg_initialized) { info_count = PROCESSOR_SET_BASIC_INFO_COUNT; if (processor_set_info (default_set, PROCESSOR_SET_BASIC_INFO, &host, (processor_set_info_t) &info, &info_count) != KERN_SUCCESS) getloadavg_initialized = 0; else { if (nelem > 0) loadavg[elem++] = (double) info.load_average / LOAD_SCALE; } } if (!getloadavg_initialized) return -1; #endif /* NeXT */ #if !defined (LDAV_DONE) && defined (UMAX) #define LDAV_DONE /* UMAX 4.2, which runs on the Encore Multimax multiprocessor, does not have a /dev/kmem. Information about the workings of the running kernel can be gathered with inq_stats system calls. We only know how to get the 1-minute average for this system. */ struct proc_summary proc_sum_data; struct stat_descr proc_info; double load; REGISTER unsigned int i, j; if (cpus == 0) { REGISTER unsigned int c, i; struct cpu_config conf; struct stat_descr desc; desc.sd_next = 0; desc.sd_subsys = SUBSYS_CPU; desc.sd_type = CPUTYPE_CONFIG; desc.sd_addr = (char *) &conf; desc.sd_size = sizeof conf; if (inq_stats (1, &desc)) return -1; c = 0; for (i = 0; i < conf.config_maxclass; ++i) { struct class_stats stats; memset ((char *) &stats, 0, sizeof stats); desc.sd_type = CPUTYPE_CLASS; desc.sd_objid = i; desc.sd_addr = (char *) &stats; desc.sd_size = sizeof stats; if (inq_stats (1, &desc)) return -1; c += stats.class_numcpus; } cpus = c; samples = cpus < 2 ? 3 : (2 * cpus / 3); } proc_info.sd_next = 0; proc_info.sd_subsys = SUBSYS_PROC; proc_info.sd_type = PROCTYPE_SUMMARY; proc_info.sd_addr = (char *) &proc_sum_data; proc_info.sd_size = sizeof (struct proc_summary); proc_info.sd_sizeused = 0; if (inq_stats (1, &proc_info) != 0) return -1; load = proc_sum_data.ps_nrunnable; j = 0; for (i = samples - 1; i > 0; --i) { load += proc_sum_data.ps_nrun[j]; if (j++ == PS_NRUNSIZE) j = 0; } if (nelem > 0) loadavg[elem++] = load / samples / cpus; #endif /* UMAX */ #if !defined (LDAV_DONE) && defined (DGUX) #define LDAV_DONE /* This call can return -1 for an error, but with good args it's not supposed to fail. The first argument is for no apparent reason of type `long int *'. */ dg_sys_info ((long int *) &load_info, DG_SYS_INFO_LOAD_INFO_TYPE, DG_SYS_INFO_LOAD_VERSION_0); if (nelem > 0) loadavg[elem++] = load_info.one_minute; if (nelem > 1) loadavg[elem++] = load_info.five_minute; if (nelem > 2) loadavg[elem++] = load_info.fifteen_minute; #endif /* DGUX */ #if !defined (LDAV_DONE) && defined (OSF_MIPS) #define LDAV_DONE struct tbl_loadavg load_ave; table (TBL_LOADAVG, 0, &load_ave, 1, sizeof (load_ave)); loadavg[elem++] = (load_ave.tl_lscale == 0 ? load_ave.tl_avenrun.d[0] : (load_ave.tl_avenrun.l[0] / (double) load_ave.tl_lscale)); #endif /* OSF_MIPS */ #if !defined (LDAV_DONE) && (defined (WIN32_NATIVE) || defined (CYGWIN)) #define LDAV_DONE /* A faithful emulation is going to have to be saved for a rainy day. */ for ( ; elem < nelem; elem++) { loadavg[elem] = 0.0; } #endif /* WIN32_NATIVE or CYGWIN */ #if !defined (LDAV_DONE) && defined (OSF_ALPHA) #define LDAV_DONE struct tbl_loadavg load_ave; table (TBL_LOADAVG, 0, &load_ave, 1, sizeof (load_ave)); for (elem = 0; elem < nelem; elem++) loadavg[elem] = (load_ave.tl_lscale == 0 ? load_ave.tl_avenrun.d[elem] : (load_ave.tl_avenrun.l[elem] / (double) load_ave.tl_lscale)); #endif /* OSF_ALPHA */ #if !defined (LDAV_DONE) && defined(LOAD_AVE_TYPE) /* UNIX-specific code -- read the average from /dev/kmem. */ #define LDAV_PRIVILEGED /* This code requires special installation. */ LOAD_AVE_TYPE load_ave[3]; /* Get the address of LDAV_SYMBOL. */ if (offset == 0) { #ifndef sgi #ifndef NLIST_STRUCT strcpy (nl[0].n_name, LDAV_SYMBOL); strcpy (nl[1].n_name, ""); #else /* NLIST_STRUCT */ #ifdef NLIST_NAME_UNION nl[0].n_un.n_name = LDAV_SYMBOL; nl[1].n_un.n_name = 0; #else /* not NLIST_NAME_UNION */ nl[0].n_name = (char *) LDAV_SYMBOL; nl[1].n_name = 0; #endif /* not NLIST_NAME_UNION */ #endif /* NLIST_STRUCT */ #ifndef SUNOS_5 if ( #if !(defined (_AIX) && !defined (ps2)) nlist (KERNEL_FILE, nl) #else /* _AIX */ knlist (nl, 1, sizeof (nl[0])) #endif >= 0) /* Omit "&& nl[0].n_type != 0 " -- it breaks on Sun386i. */ { #ifdef FIXUP_KERNEL_SYMBOL_ADDR FIXUP_KERNEL_SYMBOL_ADDR (nl); #endif offset = nl[0].n_value; } #endif /* !SUNOS_5 */ #else /* sgi */ int ldav_off; ldav_off = sysmp (MP_KERNADDR, MPKA_AVENRUN); if (ldav_off != -1) offset = (long) ldav_off & 0x7fffffff; #endif /* sgi */ } /* Make sure we have /dev/kmem open. */ if (!getloadavg_initialized) { #ifndef SUNOS_5 channel = open ("/dev/kmem", 0); if (channel >= 0) { /* Set the channel to close on exec, so it does not litter any child's descriptor table. */ #ifdef FD_SETFD #ifndef FD_CLOEXEC #define FD_CLOEXEC 1 #endif (void) fcntl (channel, F_SETFD, FD_CLOEXEC); #endif getloadavg_initialized = 1; } #else /* SUNOS_5 */ /* We pass 0 for the kernel, corefile, and swapfile names to use the currently running kernel. */ kd = kvm_open (0, 0, 0, O_RDONLY, 0); if (kd != 0) { /* nlist the currently running kernel. */ kvm_nlist (kd, nl); offset = nl[0].n_value; getloadavg_initialized = 1; } #endif /* SUNOS_5 */ } /* If we can, get the load average values. */ if (offset && getloadavg_initialized) { /* Try to read the load. */ #ifndef SUNOS_5 if (lseek (channel, offset, 0) == -1L || read (channel, (char *) load_ave, sizeof (load_ave)) != sizeof (load_ave)) { close (channel); getloadavg_initialized = 0; } #else /* SUNOS_5 */ if (kvm_read (kd, offset, (char *) load_ave, sizeof (load_ave)) != sizeof (load_ave)) { kvm_close (kd); getloadavg_initialized = 0; } #endif /* SUNOS_5 */ } if (offset == 0 || !getloadavg_initialized) return -1; if (nelem > 0) loadavg[elem++] = LDAV_CVT (load_ave[0]); if (nelem > 1) loadavg[elem++] = LDAV_CVT (load_ave[1]); if (nelem > 2) loadavg[elem++] = LDAV_CVT (load_ave[2]); #define LDAV_DONE #endif /* !LDAV_DONE && LOAD_AVE_TYPE */ return elem; }
int main(int argc, char *argv[]) { kern_return_t ret; unsigned int size, count; char *cpu_name, *cpu_subname; int i; int mib[2]; size_t len; uint64_t memsize; processor_set_name_port_t default_pset; host_name_port_t host; struct processor_set_basic_info basic_info; struct processor_set_load_info load_info; host = mach_host_self(); ret = host_kernel_version(host, version); if (ret != KERN_SUCCESS) { mach_error(argv[0], ret); exit(EXIT_FAILURE); } printf("Mach kernel version:\n\t %s\n", version); size = sizeof(hi)/sizeof(int); ret = host_info(host, HOST_BASIC_INFO, (host_info_t)&hi, &size); if (ret != KERN_SUCCESS) { mach_error(argv[0], ret); exit(EXIT_FAILURE); } ret = processor_set_default(host, &default_pset); if (ret != KERN_SUCCESS) { mach_error(argv[0], ret); exit(EXIT_FAILURE); } count = PROCESSOR_SET_BASIC_INFO_COUNT; ret = processor_set_info(default_pset, PROCESSOR_SET_BASIC_INFO, &host, (processor_set_info_t)&basic_info, &count); if (ret != KERN_SUCCESS) { mach_error(argv[0], ret); exit(EXIT_FAILURE); } count = PROCESSOR_SET_LOAD_INFO_COUNT; ret = processor_set_statistics(default_pset, PROCESSOR_SET_LOAD_INFO, (processor_set_info_t)&load_info, &count); if (ret != KERN_SUCCESS) { mach_error(argv[0], ret); exit(EXIT_FAILURE); } mib[0] = CTL_HW; mib[1] = HW_MEMSIZE; len = sizeof(memsize); memsize = 0L; if(sysctl(mib, 2, &memsize, &len, NULL, 0 ) == -1) { perror("sysctl"); exit(EXIT_FAILURE); } if (hi.max_cpus > 1) printf("Kernel configured for up to %d processors.\n", hi.max_cpus); else printf("Kernel configured for a single processor only.\n"); printf("%d processor%s physically available.\n", hi.physical_cpu, (hi.physical_cpu > 1) ? "s are" : " is"); printf("%d processor%s logically available.\n", hi.logical_cpu, (hi.logical_cpu > 1) ? "s are" : " is"); printf("Processor type:"); slot_name(hi.cpu_type, hi.cpu_subtype, &cpu_name, &cpu_subname); printf(" %s (%s)\n", cpu_name, cpu_subname); printf("Processor%s active:", (hi.avail_cpus > 1) ? "s" : ""); for (i = 0; i < hi.avail_cpus; i++) printf(" %d", i); printf("\n"); if (((float)memsize / (1024.0 * 1024.0)) >= 1024.0) printf("Primary memory available: %.2f gigabytes\n", (float)memsize/(1024.0*1024.0*1024.0)); else printf("Primary memory available: %.2f megabytes\n", (float)memsize/(1024.0*1024.0)); printf("Default processor set: %d tasks, %d threads, %d processors\n", load_info.task_count, load_info.thread_count, basic_info.processor_count); printf("Load average: %d.%02d, Mach factor: %d.%02d\n", load_info.load_average/LOAD_SCALE, (load_info.load_average%LOAD_SCALE)/10, load_info.mach_factor/LOAD_SCALE, (load_info.mach_factor%LOAD_SCALE)/10); exit(0); }